"FEEDING GRANULAR MATERIAL INTO A GAS STREAM"
This invention relates, in one aspect, to the feeding of granular material into a gas stream and in such aspect has particular, though by no means exclusive, application to the feeding of grain or fertilizer into an airstream of a seeder or broadcaster. In a further aspect, the invention relates to the distribution of granular material borne by a single gas stream into several separated streams.
The entrainment of seed into airstreams for distribution to the sowing tines of a tractor-drawn seeder has proven less than wholly successful with lighter-weight seed, such as that of clover. In general, the high speed airstream tends to oppose successful entrainment of seed and, indeed, diversion of air into the seed stream prior to entrainment is not unknown. The lighter and/or smaller the individual seeds, the greater the difficulty, and various proposals have therefore been put forward for driving the seed into the stream. One such proposal is to pressurise the seed bin; another is to employ a rotary airlock valve to control seed supply to the airstream. However, where
it is desired to entrain a mixture of seed and a fertilizer such as superphosphate, compression of the fertilizer may cause it to bridge or otherwise coagulate, thus clogging the seed supply line. All of these problems are magnified in the case of wideline seeders or seeder/broadcasters, in which air entrainment of the seed is especially attractive but which require a high initial air pressure and speed. A further proposal to meet these difficulties is to feed the seed or fertilizer into a nip formed between a pair of oppositely rotating rollers. The granules are taken into the nip and directed on exit into the multiple airs tream s. However, this arrangement remains susceptible to irregularity of supply and the rollers can easily be clogged. It is found that a substantial counteracting back pressure exists where the granules are simply dropped into each airstreamsand that there is uneveness of supply to the airstreams of a multiple set.
It is an object of the invention to provide a novel method of, and apparatus for, feeding granular material into a gas stream whereby to at least in part alleviate the aforementioned problems. It has been realized, in accordance with the invention, that an effective approach is to provide for the granular material to be metered into a feed nip, and, preferably, to divide the granular flow at the metering means rather than on entrainment. It is also preferred to introduce the granular material into the gas streams) by use of discrete venturi means for each stream.
The invention provides, in one aspect, apparatus for feeding granular material into a
gas stream, comprising:- a receptacle for granular material; a duct for constraining a gas stream; a pair of resiliently compressible surfaces which contact or almost contact to define a nip between them, the surfaces being disposed so that granular material may pass from one side of the nip through a port into said duct and being moveable into the nip from the other side thereof; and metering means defining a controllable outlet from said receptacle and being positioned with respect to said nip for feeding granular material into said nip from said other side thereof at an adjustable controlled rate. Preferably said duct is one of a plurality of ducts with associated parts arranged side by side, and said metering means comprises structure defining an array of multiple primary openings from said receptacle, which openings and ports are in register having regard to the direction of flow of granular material to the ducts in use of the apparatus . The metering means may further include, a shutter mounted for sliding movement with respect to said openings to simultaneously vary their effective size, and control means to effect said movement of the shutter.
Advantageously, said apparatus further includes, between said metering means and said nip, a partition which is formed with a plurality of parallel slots in register with said primary openings and said ports having regard to said direction of flow of granular material to the ducts in use of the apparatus.
The or each duct preferably includes venturi
means for introducing additional gas into the duct. The resiliently compressible surfaces advantageously comprise the cylindrical surfaces of a pair of rollers which touch to form said nip and may be roughened to enhance engagement with the granular material.
For enhanced agricultural applications there may be a pair of receptacles for granular material and independent said metering means associated with each receptacle.
Once the seed and/ or fertiliser is entrained in primary air streams of a wideline seeder/broadcaster the seed is carried by the primary streams to respective secondary distributors for conveyance to a multiplicity of delivery tubes or feet arranged adjacent the ground and often close behind respective cultivator tines. It is imperative that the distribution be on a uniform basis if uneven sowing of a crop is to be avoided. In a second aspect of the invention, there is accordingly provided a distributor especially adaptable to distribution of gas entrained granular material into a plurality of individual gas streams, comprising:- a transversely closed housing defining a passageway which widens gradually in a lengthwise direction from one end of the passageway to another, elongate , end ; a restriction in said passageway intermediate said ends, whereby the cross-section of the passageway at the restriction is elongate in a direction substantially parallel to the elongate dimension of said other end and, in this direction, converges from each of its extremities to a minimum height at its centre; and
one or more inclined surfaces disposed in said passageway to deflect the bulk of gas-entrained granular material entering at said one end, through said restriction such that the flows to either side of said centre of the restriction are substantially identical.
The invention will be further described, by way of example only, with reference to the accompanying drawings, in which:- Figure 1 is a somewhat schematic, partly sectioned, side elevational view of an agricultural wideline seeder/broadcaster assembled from a feed unit and distributors in accordance with the different aspects of the invention;
Figure 2 is a plan view of the assembly shown in Figure 1;
Figure 3 is. a partial cross-section on the line 3-3 in Figure 2, and depicts details of the feed unit forming part of the assembly of Figure 1; Figure 4 is a partial cross-section on the line 4-4 in Figure 3;
Figure 5 is an exploded perspective view of the principal elements visible in Figure 3;
Figure 6 is a plan view of a first embodiment of distributor for the assembly depicted in Figure 1 with the cover removed;
Figure 7 is a cross-section on the line 7 - 7 in Figure 6.
Figures 8 and 9 are respectively perspective and plan views of a second embodiment of districutor, shown with its cover removed; and
Figures 10 and 11 are respective cross-sections on the lines 10 - 10 and 11-11 in Figures 9 and 10.
The seeder/broadcaster 1 illustrated in the drawings includes, as separate wheeled implements, a feed unit 11 and a rearward wideline frame 13. unit 11 has a chassis 12 fitted with a pair of rear ground wheels 14 and with a forward hitch 16. An airline 18 comprises a plurality of side-by-side closed tubes 18a (eight as illustrated and typically between six and twelve) projecting rearwardly atop the chassis from a tapered manifold 19 to which air is supplied by a forwardly mounted blower 22. Blower 22 is coupled by a belt drive to an overhead motor 21 and is connected to manifold 19 to develop in tubes 18a equal, rearwardly moving primary airstrearns which are injected into respective larger ducts 20. In use of the assembly these streams receive seed and/or fertiliser by way of a feed device 30.
Downstream of the feed device, ducts 20 terminate at discrete nipples 24 which detachedly mount individual flexible conduits 26. These conduits convey the primary seed-bearing airstreams to respective secondary distributors 70. From here, uniform secondary streams of seed-laden air, in this case seven Streams per distributor, are conveyed along small diameter conduits 72 which terminate as delivery tubes or feet 74 immediately adjacent respective cultivation tines 76. Distributors 70 are fixed to rearward frame 13 atop individual supports (not shown) spaced across the frame, while tines 76 are suspended in offset rows from chassis 13, being typically biased downwardly
by heavy coil springs (not shown). Frame 13 includes ground wheels 79 and draughting means comprising draw bars 78 and ties 78a which merge at a forward tractor hitch 79a. Unit 11 is hitched to frame 13 via hitch 16 and is so dimensioned that it is located above draw bars 78 with its ground wheels 14 between bars 78 and ties 78a.
Mounted atop chassis 12.on a generally rectangular stand 27 having end legs 27a and lengthwise joists 27b, is a seed/fertiliser bin 28 with forward and rearward storage compartments 28a, 28b, (Figure 3) separated by an internal partition (not shown). Feed device 30 is disposed between the lower outlet of this bin and the ducts 20 for mixing the contents of compartments 28a, 28b if necessary and thenfeeding seed and/or fertiliser, in accordance with the invention, from bin 28 into the airstreams within ducts 20. By mounting bin 28, blower 22 and feed device 30 forwardly of ground wheels 14, the share of the weight load borne by these wheels is minimised, and is transferred through the hitch to the tractor. The pressure of wheels 14 on the underlying ground is thereby reduced, thus lessening undesirable compaction of the ground.
Device 30 includes (Figure 3) a pair of oppositely rotatable rollers 32 each having an annular surface layer 33 of a resiliently compressible material, which may conveniently be plastics foam, foam rubber, insert rubber or the like. Rollers 32 are mounted within a close fitting casing 36 on axles 38 so that the plane containing the axles is horizontal. The rollers are so spaced that their cylindrical surfaces 34 just touch to define a nip 40 which
receives seed/fertiliser falling from compartments 28a, 28b (by means to be hereinafter described! and from which the seed/fertiliser may fall through ports 52 to ducts 20/ Rollers 32 are arranged to be oppositely rotated so as to move surfaces 34 into nip 40 from above, at a speed in direct proportion to the speed of ground wheels 14. This is achieved by a drive consisting of a small rear wheel 58 (Figure 2, omitted from Figure 11 supported by chassis 12 in friction driveable contact with one of ground wheels 14, and a chain 60 CFigure 1 and 4) transmitting ground speed directly to the nearer roller 32 vial sprocket 61 CFigure 41 and oppositely to the further roller. The moving surfaces 34 thereby pick up the seed/ fertiliser and pass it through the nip 40 towards port 51, at a rate proportional to ground speed. Casing 36 is fixedly suspended from bin 28. It comprises end walls 42 Cone visible in Figure 4} and respective front and back walls 44, 45 (Figure 3) which are both lined with rubber 44a, 45a in light contact with the surfaces 34 of their respective nearest roller. Walls 42 may also be rubber-lined if necessary, in contact with the ends of the rollers. Attached to the underside of casing 36 is a housing 46 of triangular configuration. The attachment is depicted in Figure 3 as a screw or rivet fastening to walls 44, 45, but it is preferable that the two parts be readily separable to permit cleaning and servicing of the device. By way of example, housing 46 might hook onto wall 44 at one side and be clamped into place at the other.
Housing 46 encloses chamber 47 and includes
a pair of inclined walls 48, 48a which converge away from nip 40 to an apex ridge 48b. Ducts 20 open into chamber 47 at apex ridge 48a to define a linear array of ports 52. It will be noted that forward inclined wall 48 is contiguous with the lower edges of ducts 20 so that the axes of ducts 20 are inclined, at about 45º, to the direction of flow of the granular material from nip 40. One end wall, 50a, of housing 46 is welded to walls 48, 48a, but the other, 50b, is integral with a removable unit 49 which provides baffles 51a to divide chamber 47 into respective feed cavities 47a for ports 52. Baffles 51a and end wall 50b are fixed to a V- section slide 43 complementary to housing 46: end wall 50b may be detachably fastened to walls 48, 48a to hold baffle unit 49 in place, and yet permit its ready removal for cleaning or inspection.
Tubes 18a terminate at nozzles 18b which form restrictions at bends 20a in ducts 20. This provides respective venturi means at 17 by which air injected from nozzles 18b draws further air through apertures 17a in housing wall 48. Such is found to be very effective in entraining granules falling from nip 40 while minimising back pressure and turbulence. Each tube 18a is co-axial with the associated duct 20 downstream of nozzle 18b.
Above nip 40, slanted end walls, 37, 39 of bin 28 converge downwardly inwardly towards respective metering means 50, 51 defining outlets from compartments 28a, 28b and positioned with respect to nip 40 for feeding granular material into the nip at an adjustable controlled rate. The centre partition of bin 28 is bifurcated at its lower end to form spaced vertical wall segments 53, 55 above the respective
rollers 32. Segments 53, 55 respectively mount metering means 50, 51.
Wall segments 53, 55 are notched to form linear arrays of rectangular openings 84 (eight per array as illustrated) in vertical register with ducts
20, ports 52 and cavities 47 having regard to the direction of flow of granular material to ports 52. By "vertical register" is meant that granular material falling from an opening 84 will fall directly to a matching port 52 and duct 20 through a respective cavity 47. The other sides of openings 84 are closed by a flexible mat 80 that rests on and conforms to the uppermost portion of roller surfaces 34. Mat 80 is fastened to walls 44, 45 of casing 36 by linear brackets 81 and sags towards nip 40 between the rollers. This sagged portion is formed with slots 82 in vertical register with openings 84 and ports 52, and of similar breadth to openings 84. It will be noted that mat 80 forms the lowermost wali of the bin and seals of casing 36 to the outside of rollers 32.
The apertures 84 of each metering means 50, 51 are controlled by a pair of shutters 86, 88. Crossshutter 86 is slidable, by rotation of an external nut on a threaded stud 87 welded to the shutter, across the inside of the openings 84 and defines a further array of openings 90 which match openings 84 in dimensions and placement. In this way, shutter 86 may be employed as a slidable screening device to vary the effective width of the individual openings 84 according to the desired sizes of the granules to be sown or broadcast.
Shutters 88 are of simple rectangular form and are slidable up and down (in tracks not shown) on the outside of wall segments 53, 55 to vary the effective vertical height of apertures 84 and accordingly the rate at which the contents of the respective bin compartment are fed to the nip 40.
The mechanisms for adjusting shutters 88 include rotatable levers 92 accessible at the outside of one of casing end walls 42. Each lever 92 includes a spindle 94 which fixedly carries a transversely protruding bifurcated lug 96 (Figure 3). Lug 96 engages a pin 98 on shutter 88 so that rotation of each lever 92 effects vertical sliding movement of the associated shutter. A graduated scale is marked on a cover plate 98 (Figures 1 and 4) depending from bin 28: the lever may be clamped at any selected position on the scale.
Disposed above the metering means 50, 51 in each compartment of the bin are respective rectangular plates 89 which are hinged at 89a to wall segments 53, 55 and supported in an inclined position as shown (Figure 3) by chains 91. In use of the unit, these plates bear a substantial portion of the weight of granular material in the bin, while leaving sufficient clearance for the material to pass to the metering means. The chains are suspended at the top of the bin and may be released for dropping the plates to inspect the area below them.
A numver of optional features, not illustrated, will now be briefly discussed. Baffles 51a may be extended upwardly to define curved edges in close proximity to rollers 32. This modification might prove necessary in some cases to prevent turbulent conveyance of individual granules, especially small granules, to ducts other than those immediately below the granules' points of exit from nip 40.
With smaller granules, or granules which are inclined to coagulate or are to be metered out at a low rate or tend to be whiskered, it is thought
preferable to provide for roller surfaces 34 to be roughened, such as by elongate ribbing or by mulitiple fine nodules, preferably peaked. The ribbing advantageously exhibits a uniform zig-zag triangular crosssection and preferably extends parallel to the roller axes. Barley grain, in particular, is occasionally whiskered, in which case it may lodge in and block an opening through shutters 86, 88. Ribbing on rollers 32 assists in disloging such granules, generally enhances uniformity of flow and is found especially useful in improving the accuracy of precision planting of grain such as sorghum and sunflower.
Finally, it may be desirable to provide for a horizontal shutter to slide over partition 80 and under wall segments 53, 55 to act as a lock gate for the bin when unit 11 is transported or stored with seed or fertilizer in the bin.
In use, the illustrated assembly is drawn behind a tractor over the land to be sown. Blower 22 is activated by motor 21 to fill manifold 19 and the motion of ground wheels 14 translated into mutually opposite rotation of rollers 32. Shutters 86, 88 are moved to control the rates of feed of the seed and/or
fertilizer from the compartments of the filled bin 28, and to screen the size of granules passed to the roller nip. A metered amount of seed and fertilizer of refined granule size is thereby allowed to fall through slots 82 into nip 40, which takes the seed up and in turn directs it into chamber 47. Here the seed/fertilizer falls through cavities 47a to ports 52 and is entrained by the ventuti-enhanced airstreams in ducts 20, air being ejected from manifold 19 at nozzles 18b and being drawn through apertures 17a. Because the surfaces 34 of rollers 32 are resiliently compressible, the seed is positively picked up and directed for entrainment into the airstreams but is not damaged: these criteria determine the thickness of surface layers 34. On the other hand the contact of surfaces 34 at nip 40 prevents both diversion of air into the seed stream and reversed travel of lighter seeds, such as clover, away from the airstream by turbulence. The contact between the roller surfaces and both the walls 44, 45 of casing 36 and the mat 80 minimizes travel of air about the rollers to the vicinity of openings 50 and the supply side of the nip. The provision of metering means 50, 51 in advance of the nip ensures even flow without clogging or bridging. The presence of openings 84 and slots 82, and their vertical registration with cavities 47a and ports 52, is believed to assist in obtaining a uniform distribution of granules across all of the ducts 20.
Turning now to the structure of distributors 70, a representative distributor is depicted in detail in Figures 6 and 7. Each distributor includes a transversely closed metal housing 102 defining a passageway 104 which widens gradually and uniformly with an included angle between 30 and 40 from a forward, substantially square intake port 106 to a rearward, transversely elongate, arcuate exhaust end of transverse dimension about 3.3. times the diameter of
port 106. Housing 102 comprises diverging side walls
102a, 102b, a base wall 102c and a cover 102d, which is separable from the other side walls and which converges towards base wall 102c in the upstream direction. Provision (not shown) is made for ready release of the cover in order to service or check the distributor.
The respective supply conduit 26 is coupled to the intake port 106 by a round-to-square adapter piece 100 which is clamped onto the conduit and fastened about port 106. The individual conduits 72 feeding the delivery tubes 74 carry square metal spigots 107 and these are welded in a row into the exhaust end to define respective exhaust ports 108 from passageway 104. Located within housing 102 is means defining a conical obstruction 112 in passageway 104 intermediate ports 106, 108. The base rim 114 of this cone rests on and is welded to the inner surface of base wall 102c while its apex 116 is spaced from cover 102d by a clearance 118 which is small relative to the height of the cone. The cone axis lies in a plane which is normal to the direction of divergence of the housing and to the elongate dimension of exhaust port 108. The axis is also somewhat closer to intake port 06 than to exhaust poris 108. If convenient, the cone may be fixed to the underside of cover lθ2d rather than to base wall 102c.
It will be appreciated that conical obstruction 112 defines a restriction in passageway 104. The crosssection of the passageway at the restriction is elongate in a direction parallel to the elongate dimension of exhaust port 108 and, in this direction, converges from each, of its extremities to a minimum height
at appex 116. Obstruction 112 further defines a lead-in surface to deflect the bulk of gas entrained material entering at said one end, through the restriction such that the flows to either side of apex 116 are substantially identical.
Distributors constructed in this manner are found to ensure a very even distribution of seed borne by the primary airstream in conduit 26 among the secondary airstreams in conduits 72. The direction of seed flow about the conical surface of obstruction 102 generally normal to the axis of the cone rather than onto the conical surface parallel to this axis appears at present to be the effective operational feature. The conical surface need not be complete but may be part-conical, or indeed inverted conical. There may be more than one such surfaces, which may be supported from the cover rather than from the base wall of the housing.
It has been found that the distributor embodiment shown in Figures 6 and 7 is highly satisfactory for wideline seeder/broadcasters of small to medium width, typically requiring four to seven downstream delivery tubes per distributor. Differences of sewing or broadcasting rates as between the delivery tubes of each distributor are well within acceptable margins of deviation. However, these differences have sometimes proven less than acceptable in the case of very broad wideline units in which limitations on the number of primary feedlines to the distributors necessitates eight to twelve delivery tubes per distributor. Reliability is also affected, for reasons which are unclear, where very broad wideline units are operating in high winds. The embodiment 70' depicted in Figures 8 to 11 in which like reference numerals indicate like parts, has proven successful in alleviating these difficulties.
in this embodiment, the conical obstruction 112 is supplanted by a pair of plates 140, 150 disposed in, and extend transversely of passageway 104'. Both plates are welded to side walls 102'a, 102'b. The plates are of approximately equal extent in, and are inclined to, the general direction of air flow through the passageway. Downstream plate 140 serves to define a restriction 142 in passageway 104' and a primary deflecting surface Ϊ44 (Figure 10) to deflect entering granular material through restriction 142.
The plate is slightly bent along two oblique fold lines 146a, 146b to give rise (Figures 8 and 11) to a straight upstream edge 147 extending parallel to base wall 102'c, and a shallow-V upstream edge 148 defining restriction 142. The cross-section of the passageway at the restriction is thereby elongate in a direction parallel to the elongate dimension of the exhaust end and, in this direction, converges from each of its extremities to a minimum height at the nadir 149 of plate 140 at the centre of the restriction. Deflecting surface 144 is somewhat complex and essentially part-conical in three flats. The arrangement is symmetrical, so as to achieve substantially identical flows to either side of nadir 149.
Upstream plate 150 is flat and defines a further deflecting surface 152 effective to direct the bulk of the entering gas-entrained granular material towards the upstream region of surface 144, displaced from restriction 142. In essence, the granular material approaches the surface 144, the primary deflecting surface, as a band extending across the passageway; this motion is indicated by arrows 160 in Figure 10 :
the granular material is deflected first by a surface, typically a top surface, of plate 150, and then by an undersurface of the second-encountered plate 140. With this arrangement it is found that an even distribution of the granular material is obtained across the outlet end of housing 102, and thus across the outlet ports 108.
It will be observed that there is a clearance 141, 151 between the respective upstream edges of plate 140, 150 and the housing base or cover. Although some seed or fertiliser will traverse these clearances, the spaces above plate 140 and under plate 150 will thereby not be deadspaces which might induce bridging or clogging of the granular material. The angles of inclination of surfaces 144, 152 to an imaginary line 162 (Figure 10) joining the centres of the intake end and the exhaust end are preferably in the respective ranges 15° to 40° and 5° to 25°, most preferably about 25° and 15°. It will also be observed that the upstream margin 154 of surface 152 is closely adjacent intake port 106' while, along line 162, the upstream edge 147 of plate 140 is spaced from the downstream edge 156 of plate 150 by a distance a little less than half the extent of each plate.
In a practical embodiment, the precise positioning and inclination of plates 140, 150 for ideal performance may prove to be a matter of experiment. Figures 8 to 11 depict an exemplary distributor unit to scale, but relative adjustments of parameters may prove necessary in practice for optimum performance.